One-pot stereocontrolled cycloalkanone synthesis using 1,3-dithiane 1-oxides

00404039193 56.00 + .oO PcrgReds lad

Temhedmn Leaen. Vol. 34, No. 43. PP. 69474950.1993 RintCdiIlGMtBli&

One-Pot Stereocontrolled Cycloalkanone Synthesis using 1,3-Dithiane 1-Oxides Philip

C. Bulman Paae.’ Stephen J. Shuttleworth. Hark B. Schilihg.~ David J. Tapokzayt

Robert Robinson Labmatories~.Department of Chemistry, uliverslty of uverpool. oxford sbet# UveIpool L69 3Bx. En@aand hlxEss Research Depzumlcnt aaxo aroup Research LUl.. Qreenfard Road. Qmford. Middlesex lJB6 OIIE, England

Abstract: Ldthium enolates of Zacyl-1,Sdithiane l-oxides, generated in one pot from 1.3-dithiane l-oxide, undergo highly diastereoselective alkylation upon treatment with alkyl iodide% similar In slfu treatment of these substrates with diiodoalkanes furnishes the corresponding medium-ring cycloalkanones with extremely high diastereoselectivity and in moderate to good yields. Over recent years we have developed the uses of simple IJ-dithiane l-oxide (DITOX) derivatives as chiral auxiliaries and asymmetric building blocks for the enantiocontrol of a range of organic reactions including enolate alkylation,l C3rignard reagent addition.2 hydride reduction.3 conjugate addition.+ and heterocycloadditloms more recently the Mannich reaction has been studied in an enantioselective approach to amine&s In most of these cases, the observed stereoselectivities are suMciently high that the minor isomers are not detectable by 400 MHz 1H NMRspectroscopy. The high degree of stereoselectivity observed in these reactions may be rationalized in terms of an association of both the enolate and the sulphoxide oxygen atoms with a metal counter-ion which forces the system into a conformation in which the acyl moiety is held in a highly asymmetric environment (Figure). This simple chelationcontrol model allows us eastly and successfully to predict the sense of induced stereochemistry in each reaction type. The DITOX unit may be removed from 2-acyl-2 alkyl-13-dithiane l-oxides by treatment with base or through hydrolysis.7 We have recently become interested in the possible application of these concepts to the use of DITOX building blocks in stereocontrolled cycllzatlon.

6947

An efficient method for preparation of the 2acyi-2-alkyi-1,3-dithiane l-oxide substrates in optically pure form has until recently been lacking. However, lately we have made two considerable advances in the preparation of acyl dithiane oxides: we are able to prepare 1,34thiane l-oxide (DITOX) enanttomericaily pure in both enantiomeric forms.7 and we have solved the unexpectedly diMcult problem of acylation of DITOX itself. Acylation is eMciently effected using nacyi imidazoies under mixed base (sodium hexamethyl disilazide/butyi lithium) conditions furnishing 2acyi-1.3-dithiane l-oxides in good yields atIer protic work-up.8 Table I. Perkin Ring Synthesis using 1.bDithiane

f-l

s,,s:o_

1-Oxides

n

1. NHMD8 (2.2 equiv.), THF, -20 ‘C, 30 min;

S

0

2. Br(CHz),Br (2.0 equiv.), -78 ‘C to r.t., 16 h

n 4

Yield/% 75

SC0-

1n-3

;: _t

: 7 t uncyclized haloalkylated

material (62%) isolated

We have found that anions derived from dithiane oxide substrates undergo efficient Perkin ring synthesis upon treatment with dihaloalkanes (Table I) to provide up to seven membered carbocycies, 1,7-dibromoheptane providing the haioalkylated material but not ungergoing cyclization to the eight membered ring. However, this process introduces no new asymmetric centres. We reasoned that suitable deprotonation of our 2-acyl-1,3dithiane l-oxides followed by treatment with dihaioalkanes should lead, by tandem interand intra- molecular enolate alkylation, to carbocycles, with a strong possibility of stereocontrol during the cyciization process (Scheme I).

n s;

n

S -

s_sto-

o-

$_ *#

(

0

”

‘+

R

Scheme I Unfortunately, we have since discovered that exposure of some isolated acyl derivatives of DITOX to silica gel for a short period of time (c ca. 2 hours) at room temperature results in transformation, perhaps through a Pummerer rearrangement process, into thiolester derivatives. Furthermore, in attempted aikylation reactions following deprotonation acyi dithiane oxide substrates were similarly transformed in the presence of stoicheiometric quantities of Lewis acid.9 As indicated above, acylation of DITOX using f%acyl imidazoles requires the use of base mixtures: the optimum procedure involves generation of the metaliated species

6949

from 1,3-dithiane l-oxide by deprotonation with a solution of sodium hexamethyl disilazide (NHMDS) (1.1 equiv.) followed by addition of a solution of butyl lithium (1.1 equiv.) at -78 “C to prevent yields being compromised by reprotonation of the dithiane oxide anion by the more acidic acyi dithiane oxide product. Consequently, upon acylation, the lithium hexamethyl disilazide generated in situ by the butyl lithium deprotonates the highly acidic proton at G2 of the acyl dithiane oxide, furnishing a lithium enoiate. Our judgement was therefore that a work-up procedure involving initial treatment with a carbon electrophile would lead to a one-pot formation of Zaikyl-Zacyi1,3_dithiane 1-oxides. normally our starting materials for stereocontrolled reactions in this series, potentially in optically pure form. Indeed, treatment of DITOX acyiation reaction mixtures with simple aikyi halides at -78 ‘C enabled us to isolate Z-aikyi-2-acyi-1,3dithiane l-oxides in moderate to good yields and with excellent diastereoselectivity (Table II). Interestingly, the isomer formed predominantly has the syn configuration; this route is therefore complementary to our earlier route involving sulphur oxidation as the final stage, which provides predominantly anti material. In addition we have discovered that the syn isomers are cleanly converted into anti by low temperature treatment with trifluoroacetic anhydride. Table II. One Pot Generation of 2-Acyl-Zalkyl- 1.3-dithiane 1-Oxides

r-l s_s+_oR

Me Me Me

0

1.NHMDS (1.1 equiv.), THF, -78 “C, 15 min; 2. BuLi (1.1 equiv.), -78 “C, 15 min; 3. RCOimid (1.1 equiv.), -78 “C to r.t., 2 h; 4. R’I (2.0 equiv.), -78 “C to r.t., 16 h . YleLQ/% WV

Me Et CH&ZHCH2 Me : CHz=CHCHp Bu Me CH2=CHCH2 SPh Me t minor isomer not detectable

65 54

f: E = dc S

‘c

R

ISV~ 7:1

exclusive t exclusive t exclusive t 15: 1 exclusive t :A 4: 1 67 exclusive t by 400 MHz IH NMRspectroscopy 73 73 75

Particularly exciting to us was the potential application of this chemistry to a stereocontrolled cyclization reaction, as originally envisaged (Scheme 1). but taking place in one pot. We were therefore especially pleased to find that sequential treatment of 1,3dithiane l-oxide with NHMDS, butyl lithium, propionyl or butyryl imidazoie, and diiodoalkane led to the corresponding haioalkylated materials, which could be isolated in ca. 70% yields and which are formed with exclusively syn stereochemistry; alternatively, further treatment with NHMDS gave in two cases cyclization to carbocyclic products with sufficiently high diastereoselectivity that the minor isomer at the new asymmetric centre in the ring could not be detected by 400 MHz IH NMR spectroscopy (Table 111).Two new asymmetric centres and two new carbon-carbon bonds are therefore each formed in these one pot cyclization reactions with extremely high stereoselectivity. Curiously It is the seven and eight membered ring compounds which are readily formed; reaction with l,J-diiodopropane gave preferential elimination of HI to provide only syn-2-aiiyt-2 propanoyl-1.9dithiane I-oxide, while 1.6-diiodohexane gave the haloalkylated material

6950

but did not undergo cyciization to the ninemembered successful substrate. Table

n s_st

%R. One Pot Stereocontrolled Cyclizatlon

ring. 1.2-Diidoethane

Reactions

1. NHMD8 (1.1 equiv.), THF, -78 “C, 15 min; 2. BuLi (1 .I equiv.), -78 OC, 15 min:

was not a

using DR’OX

n

Q 3. RCHzCOimid ( 1.1 equiv.), -78 ‘C to r.t., 2 h: 4. I(CHz),I (10 equiv.), -78 OCto r.t., 16 h; 5. NHMDS (1.1 equiv.), -78 ‘X to r.t., 16 h

Me -t Me 72 exclusive s Me 74 exclusive * 0 Me Et -tsb 24 : 1 Et 63 exclusive 4 t sy&&aiiyi-2-propanoyi-1,3-dithiane 1-oxide (78%) isolated * minor isomer not detectable by 250/400 MHz *H NMRspectroscopy 0 uncyciized haioaikyiated material (64%) isolated Inspection of molecular models suggests that the syn intermediate haioaikyiated species, expected to be predominant as described above, will lead to a stereochemistry in the cyclized product as shown, in accordance with our acyclic enolate aikyiation work.1 Presumably the conformations adopted by the intermediate are such that cyciization is favoured only for a limited range of ring sizes where the aikyi iodide chain is of an idea! length. Ackn0wled@ment This investigation

has enjoyed the support of Qiaxo CkroupResearch Ltd. (studentship to SJS). We are indebted to the SERC Very High Field NMRService at the University of Warwick for their help and patience. REPERBNCES

1. Page, P. C. 8.; Westwood, D.; Siawin, A. M. Z.; Williams, D. J. J. Chem. Sot., Perkin Trans. I, 1989,185; Page, P. C. B.; Klair, S. S.; Westwood, D. J. Chem. Sue.,Perkin Trans. I, 1989,241. 2. Page, P. C. 8.; Westwood, D.; Siawin, A. M. Z.; Williams, D. J. 1. Chem. Sot., Perkin Trans. I, 1989,115B. 3. Page, P. C. 8.; Prodger, J. C. Synlett, 1990,460. 4. Page, P. C. B.; Prodger, J. C.; Hursthouse, M.; Mazid, M. 1. Chem. Sm., Perkin Trans. 1,1990,167. 5. Page, P. C. 8.; Prodger, J. C. Synlett, 1991,84. 6. Page, P. C. B.; Allin, S. M.; Collington, E. W.; Carr, R. A. E. J. Org. Chem., 1993, in press. 7. Page, P. C. B.; Namwindwa, E. S.; Klair, S. S.; Westwood, D. Synlett, 1990,457; Page, P. C. B.; Namwindwa, E. S. Synlett, 1991,BO;Page, P. C. B.; Gareh, M. T.; Porter, R A. Tetrahedron Asymmetry., 1993, in press. 8. Page, P. C. B.; Gareh, M. T.; Porter, R. A. TefrahadronLeft., 1993, in press. 9. Page, P. C. B.; McKenzie, M. manuscript in preparation.

(Received in UK 3 August 1993;accepted 27 August 1993)